![]() M a x = l e v e l + w i n d o w / 2 max = level + window/2 m a x = l e v e l + w i n d o w / 2 We would just like the min and max of the range: It is actually quite an ugly convention for computer scientists. The medical image convention to clip the Housenfield range is by choosing a central intensity, called level and a window, as depicted: Instead, we limit our attention to different parts of this range and focus on the underlying tissues. It wouldn’t be very wise to visualize all the Hounsfield scale (from -1000 to 1000+ ) to 256 scales for medical diagnosis. The problem: visualization libraries work on the scale. For instance, the max value might be 1000, for practical reasons. We usually clip the image to have an upper maximum range. ![]() The numbers may slightly vary in real images.īones have high intensity. The image illustrates some of the basic tissues and their corresponding intensity values. It is essential to understand that Housenfield is an absolute scale, unlike MRI where we have a relative scale from 0 to 255. In this scale, we fix the Air intensity to -1000 and water to 0 intensity. The X-ray absorption is measured in the Hounsfield scale. Here is a 1 min video I found very concise: CT intensities and Hounsfield units Hess, M.D., Ph.D, and Derk Purcell, M.D, Department of Radiology and Biomedical Imaging at UCSF In this way, CT imaging is able to distinguish density differences and create a 3D image of the body. On the opposite, dense tissues are depicted as white. in the air region inside the lungs) and reach the detector we see them as black, similar to a black film. When X-rays are not absorbed from the body (i.e. bones) will absorb more radiation than soft tissues (i.e. X-rays pass through human body tissues and hits a detector on the other side. A heated cathode releases high-energy beams (electrons), which in turn release their energy as X-ray radiation. CT imaging Physics of CT ScansĬomputed Tomography (CT) uses X-ray beams to obtain 3D pixel intensities of the human body. You may skip this section if you are already familiar with CT imaging. We will start with the very basics of CT imaging. ![]() If you want to focus on medical image analysis with deep learning, I highly recommend starting from the Pytorch-based Udemy Course. To dive deeper into how AI is used in Medicine, you can’t go wrong with the AI for Medicine online course, offered by Coursera. The accompanying Google colab notebook can be found here to run the code shown in this tutorial. I also include parts of the code to facilitate the understanding of my thought process. New practitioners tend to ignore that part, but medical image analysis is still 3D image processing. It is critical to understand how far one can go without deep learning, to understand when it’s best to use it. The goal is to familiarize the reader with concepts around medical imaging and specifically Computed Tomography (CT). However, this time we will not use crazy AI but basic image processing algorithms. Time for some hands-on tutorial on medical imaging.
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